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JoVE Journal Medicine

Medicine

Research Application of Laser-Induced Shock Wave for Studying Blast-Induced Cochlear Injury

Published: March 1, 2024 doi: 10.3791/66396
1, 1, 1, 1, 2, 3, 2
1Department of Otolaryngology, Head and Neck Surgery, National Defense Medical College, 2Division of Bioinformation and Therapeutic Systems, National Defense Medical College, 3Department of Biochemistry, National Defense Medical College

Abstract

The ear is the organ most susceptible to explosion overpressure, and cochlear injuries frequently occur after blast exposure. Blast exposure can lead to sensorineural hearing loss (SNHL), which is an irreversible hearing loss that negatively affects the quality of life. Detailed blast-induced cochlear pathologies, such as the loss of hair cells, spiral ganglion neurons, cochlear synapses, and disruption of stereocilia, have been previously documented. However, determining cochlear sensorineural deterioration after a blast injury is challenging because animals exposed to blast overpressure usually experience tympanic membrane perforation (TMP), which causes concurrent conductive hearing loss. To evaluate pure sensorineural cochlear dysfunction, we developed an experimental animal model of blast-induced cochlear injury using a laser-induced shock wave. This method avoids TMP and concomitant systemic injuries and reproduces the functional decline in the SNHL component in an energy-dependent manner after LISW exposure. This animal model could be a platform for elucidating the pathological mechanisms and exploring potential treatments for blast-induced cochlear dysfunction.

Introduction

Hearing loss and tinnitus are among the most prevalent disabilities, reported in up to 62% of veterans1. Several blast-induced auditory complications, including sensorineural hearing loss (SNHL) and tympanic membrane perforation (TMP), have been reported in individuals exposed to blast overpressure2. Moreover, research on individuals exposed to blasts suggests that blast exposure frequently results in defects in auditory temporal resolution, even when the hearing thresholds are within normal range, which is known as "hidden hearing loss (HHL)"3. It is well established that there is a substantial loss of cochlear synapses between inner hair cells (IHCs) and auditory neurons (ANs) in blast-related cochlear pathology4. Synaptic degeneration results in impaired auditory processing and is a major contributing factor in the development of HHL5. Thus, auditory organs are fragile components containing complex and highly organized structures. However, the precise mechanism by which blast waves affect the inner ear at the cellular level remains unclear. This is because of the challenges in replicating the precise clinical and mechanical intricacies of blast injuries in laboratory settings and the complexity of blast-induced cochlear pathologies.

The primary component of a blast injury is the shock wave (SW), characterized by a rapid and high increase in peak pressure6. The complexity of blast injuries has been extensively investigated in numerous retrospective studies7,8,9. There are various devices for blast generation, such as compressed gas10, shock tubes11, and small-magnitude explosives12, at different levels of pressure. The pressure waveform of the SW generated by recently developed devices closely resembled that of an actual explosion. An important concept in establishing an animal model of blast-induced sensorineural hearing loss is to minimize concomitant injuries, other than auditory damage, to reduce animal death. Thus, blast injury studies have been developed in which shock tubes have been miniaturized and the output can be precisely controlled so that exposed animals rarely die. However, although these animal models usually develop complications, such as TMP, evaluation of cochlear function is difficult because of concurrent conductive hearing loss2. We previously performed an ear-protected animal study on blast injury using earplugs and found no incidence of TMP13. The earplugs could partially attenuate severe cochlear damage but not central auditory neurodegeneration or tinnitus development. Thus, earplugs protect the cochleae as well as the tympanic membrane. However, an animal model of blast-induced pure cochlear damage without TMP is required to study the cochlear pathophysiology caused by blast injuries.

We previously developed a topical blast injury model of the inner ear in rats and mice using a laser-induced shock wave (LISW)14,15. This method can be safely and easily performed at a standard laboratory level and has been used to generate models of lung and head blast injuries16,17. The energy of the LISW can be adjusted by changing the laser type and power, allowing control over the degree of cochlear damage. The LISW-induced cochlear injury model is valuable for studying the mechanisms of SNHL caused by blast injuries and investigating potential treatments. In this study, we describe detailed experimental protocols for creating a mouse model of blast-induced cochlear damage using LISW and demonstrate cochlear degeneration, including the loss of hair cells (HCs), cochlear synapses, and spiral ganglion neurons (SGNs), in an energy-dependent manner in mice following LISW exposure.

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Protocol

All experimental procedures were approved by the Institutional Animal Care and Use Committee of the National Defense Medical College (approval #18050) and performed in accordance with the guidelines of the National Institutes of Health and the Ministry of Education, Culture, Sports, Science, and Technology of Japan. All efforts were made to minimize the number of animals and their suffering.

1. Animals

  1. Use 8-week-old male CBA/J mice to follow this protocol. Before the experiment, subject the mice to a hearing function test and endoscopic observation of the tympanic membrane to ensure normality.
  2. Divide 27 CBA/J mice into three groups: (1) 2.0 J/cm2 exposed group (n = 9 mice); (2) 2.25 J/cm2 exposed group (n = 9 mice); and (3) 2.5 J/cm2 exposed group (n = 9 mice). Remove all the ears for assessment 1 month after the LISW exposure.

2. Experimental settings of LISW exposure

  1. The laser target is a black, natural rubber disk, 10 mm in diameter and 0.5 mm thick. To increase the LISW impulse, use an acrylic resin welding adhesive to bond a 1.0 mm thick, transparent, polyethylene terephthalate sheet (PET) to the top of the target area. Irradiate a 532 nm Q-switched Nd: YAG laser to generate the LISW behind the target (Figure 1A).
  2. Focus the laser pulse with a plano-convex lens to a 3.0 mm diameter spot on the laser target.
  3. Use the LISW irradiation to generate plasma at the bonding surface of the two materials and vaporize the rubber (plasma-mediated ablation), leaving vaporized rubber in the cavity.
  4. Use a hydrophone to measure the pressure wave of LISW at 1.0 mm underwater, not in living tissue. Place a 0.25 mm diameter fiber optic hydrophone under the black rubber 1.0 mm below the water surface to record the LISW pressure waveforms and measure them using a digital oscilloscope.
    NOTE: The pressure waveforms showed stable characteristics with similar maximum pressure and impulse as shown in Figure 1B.
  5. Perform all animal procedures under general anesthesia using intramuscular injections of 1 mg/kg medetomidine hydrochloride and 75 mg/kg ketamine.
  6. Carefully shave the postauricular regions to avoid retaining the trapped air in the fur. Fix the mice on a plate and position the postauricular regions in the focal area of the LISW in a vertically upward direction.
  7. Attach a black rubber target percutaneously to the postauricular region of the mouse ear. To ensure acoustic impedance matching, use an ultrasound conductive gel between the laser target and the skin surface.
  8. Apply a single LISW pulse to the cochlea via the temporal bone. Set the outputs of the laser pulses to three energy densities: 2.0 J/cm2 , 2.25 J/cm2, and 2.5 J/cm2.

3. Cochlear function test

NOTE: Auditory brainstem response (ABR) tests were performed as previously reported14,15.

  1. Perform the ABR measurement 1 day before and 1 day and 1 month after LISW exposure.
  2. ABR is an auditory evoked potential in response to auditory stimuli and is commonly used to assess hearing thresholds at four frequencies (12.0 kHz, 16.0 kHz, 20.0 kHz, and 24.0 kHz).
  3. Present the stimulation sound over a small earphone and measure the sound pressure level near the tympanic membrane of the mouse using a small microphone placed near the earphone. Output burst stimuli from a sound generator at 37 cycles/s and amplify the sound pressure from a 20 dB sound pressure level (SPL) to 80 dB SPL in 5 dB SPL steps.
  4. Insert a stainless steel needle electrode for electroencephalogram recording under the ear canal and frontal region of the ear and insert a ground electrode under the caudal region of the tail.
  5. Evaluate the cochlear functions by measuring the ABR peak I (P1) amplitude. Automatically analyze the ABR waveforms with respect to the hearing thresholds and ABR P1 amplitude using the ABR peak analysis software as previously reported18.
  6. Calculate the ABR threshold shifts by subtracting the thresholds obtained before exposure. Compare the ABR threshold shifts in the three exposed groups to those of the non-exposed contralateral ears (control). Measure ABR amplitudes using ABR waveform during 80 dB SPL stimulation.

4. Histological assessment

NOTE: Histological assessment was performed as previously described14,15.

  1. HCs and cochlear synapse
    1. Perform the pathological examination of the cochlea 1 month after LISW exposure.
    2. After hemoperfusion with lactated Ringer's solution, perform transcardiac perfusion with 1 mL/g of 4% paraformaldehyde (PFA). After decapitation, remove the cochlea and perfuse directly with 4% PFA, followed by fixation at 4 °C overnight.
    3. After fixation, decalcify the cochlea by shaking in 0.5 mol/L ethylenediaminetetraacetic acid (EDTA) solution for 2 days.
    4. Divide the demineralized cochlea into four pieces. After freezing each piece of cochlea on dry ice for 10 min, perform blocking at room temperature for 1 h in 5% normal horse serum simply conjugated with 0.3% Triton X for permeabilization.
    5. Use anti-myosin 7a (Myo7A), anti-C-terminal binding protein (CtBP2), and anti-neurofilament (NF) antibodies as primary antibodies and incubated at 37 °C overnight. Use Myo7A, CtBP2, and NF antibodies to evaluate HCs, presynaptic ribbons, and cochlear nerve fibers, respectively.
    6. Wash off the unbound primary antibody with phosphate-buffered saline (PBS) for 5 x 3 min. Incubate the specimens with the appropriate secondary antibodies at 37 °C for 2 h. After staining, wash the specimens for 3 x 5 min with PBS, and encapsulate the specimens on the slide glass with a water-soluble encapsulant using cover glass.
    7. For evaluation, acquire the entire image of the cochlea (divided into four pieces) at 10x magnification, and compute the cochlear frequency map using the referenced ImageJ software plug-in to precisely localize the specific cochlear regions at 12.0 kHz, 16.0 kHz, 20.0 kHz, and 24.0 kHz frequency.
    8. Calculate the rates of HC survival and the number of synapses at each frequency.
      1. To calculate the rates of HC survival, count the numbers of surviving and missing HCs per 200 µm length at each frequency, and calculate the survival rate of the HCs using equation (1) shown below:
        HC survival rate (%) = (Number of surviving HCs / Number of surviving and missing HCs) × 100  (1)
      2. To calculate the number of synapses, obtain high-resolution z-stack images of the inner HC area using an oil immersion objective lens (63×) with a 3.1x digital zoom and a 0.25 µm step size under confocal fluorescence microscopy. Import the image stacks to ImageJ, and automatically count the CtBP2 puncta per IHC within a 50 µm range in each image stack. Calculate the synaptic ribbons survival rate using equation (2):
        ​Synaptic ribbons survival rate (%) = (Number of synaptic ribbons in LISW exposed ears / Number of synaptic ribbons in control ears) × 100  (2)
    9. For scanning electron microscopy (SEM), remove the cochlea, as previously described, and then fix with 2% PFA and 2.5% glutaraldehyde together at 4 °C overnight. After decalcification of the cochlea by shaking in 0.5 mol/L EDTA solution at 4 °C for 7 days, dissect the cochleae into four pieces for whole-mount preparation.
    10. Fix the tissues with 1% osmium tetroxide at 4 °C for 30 min, dehydrate in 50% ethanol at room temperature for 10 min, repeat with 70 %, 80 %, 95 %, and then 100 % ethanol, sputter coating with osmium, and examine under an electron microscope at 5.0 kV, as previously reported14.
    11. Conduct a quantitative analysis of stereociliary bundle disruption in outer hair cells (OHCs) by calculating the ratio of disrupted stereocilia (number of disrupted OHC stereocilia/total number of OHC stereocilia) in each energy group using the SEM images14. Count the number of stereocilia per 100 µm at the center of the 16.0 and 24.0 kHz regions. Designate one or more rows of OHC bundles that are bent toward the lateral side, tangled, or lacking their base as disrupted.
  2. SGNs
    1. To quantitatively assess the number of SGNs at 1 month after LISW exposure, perform transcardiac perfusion with 4% PBS, decapitate, remove the cochlea, and perform posterior fixation under the same conditions as described above. Decalcify the cochlea in 0.5 M EDTA for 1 week.
    2. After decalcification, immerse the cochleae in 30% sucrose overnight, embed them in the cryosectioning compound, freeze in liquid nitrogen to prepare sections near Rosenthal's canal at a thickness of 15 µm, stain with hematoxylin and eosin, and view them under a light microscope14.
    3. For SGN density measurement, count the number of SGNs in the middle turn of the Rosenthal's canal and calculate SGN survival per control.

5. Statistical analysis

  1. Perform statistical analyses using the software of choice.
  2. Analyze statistical differences in ABR threshold shift, HC, SGN, and synaptic counts using two-way repeated-measures ANOVA ["frequency or cochlear parts (apical/middle/base)" × "animal groups"], two-way analysis of variance (ANOVA), followed by post-hoc Tukey's multiple comparison test.
  3. Present all data as mean ± standard error and set the statistical significance level at p < 0.05.

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Representative Results

LISW waveform
The reproducibility of the LISW pressure waveform was measured 5x at 2.0 J/cm2 as follows. The waveforms were generally similar and stable and showed a sharp increase with time width, peak pressure, and impulse of 0.43±0.4 µs, 92.1 ± 6.8 MPa, and 14.1 ± 1.9 Pa∙s (median ± SD), which corresponds to SW characteristics (Figure 1B). LISWs are characterized by a fast rise time, high peak pressure, short duration, and positive pressure dominance. When applied to biological tissue, the target is placed directly onto the living tissue through the jelly, and it can be considered that the SW has almost the same characteristics as the measured SW applied to the tissue. After exposure to LISW, the occurrence of TMP was assessed using a small digital endoscope. None of the mice in the LISW energy group exhibited TMP after exposure (Figure 1C).

Auditory assessment
An ABR examination was performed to determine auditory function. ABR is a measurement of the sound-evoked potential in the auditory pathway, and ABR P1 represents accumulated neural activity in the cochlear nerve. One day after LISW exposure, the exposed ear showed a significant difference in the ABR threshold shift among the different LISW groups (two-way ANOVA, p < 0.0001; Figure 2A). This increase in the ABR threshold shift persisted for up to 1 month after LISW exposure in the 2.25 and 2.5 J/cm2 groups (two-way ANOVA, 2.25 J/cm2, p < 0.0001; 2.5 J/cm2, p < 0.0001). In particular, the high-frequency region exhibited a notable increase in ABR threshold shift. However, ABR thresholds recovered to a level that was not significantly different from preirradiation in the 2.0 J group (two-way ANOVA, 2.0 J/cm2, p = 0.76), indicating that the threshold elevation was energy-dependent. Regarding ABR P1 amplitudes, all LISW-irradiated groups showed a significant decrease in ABR P1 amplitudes at all frequencies 1 day and 1 month after LISW exposure (two-way ANOVA, p < 0.0001; Figure 2B). The unexposed ear (control; left ear) exhibited no noticeable alterations in ABR hearing threshold following LISW exposure (data not shown).

Survival of HCs and SGN
Microscopic observation of LISW-exposed ears revealed no mechanical damage to the cochleae, such as fracture and dislocation of the ossicles, round window membrane rupture, or intracochlear hemorrhage, following LISW exposure (data not shown), which is consistent with previous findings6,14.

Fluorescent immunostaining of HCs with Myo7A, synaptic ribbons with CtBP2, and the cochlear nerve with NF is shown in Figure 3A. No severe cochlear damage, such as the loss of HCs or nerve fibers, was observed in any of the groups. However, the quantitative assessment of Myo7A positive OHCs survival differed significantly between the groups (two-way ANOVA, p = 0.002; Figure 3B). The 2.5 J/cm2 group showed significantly lower survival rates of OHCs than the control group, especially in the high-frequency region (two-way ANOVA, 2.5 J/cm2, p = 0.0002). However, the survival rates of IHCs were comparable among the groups, indicating that OHCs are vulnerable to high-energy LISW (two-way ANOVA, p = 0.76). A quantitative assessment of synaptic ribbon survival is shown in Figure 3C. Synaptic ribbons were significantly reduced in both the 2.25 and 2.5 J/cm2 groups compared to the control (two-way ANOVA, 2.25 J/cm2, p < 0.0001; 2.5 J/cm2, p < 0.0001), and the higher frequencies exhibited a stronger tendency to decrease, similar to that of ABR threshold shift and OHC survival.

Next, the SGN density was assessed, as shown in Figure 3D. There was a significant difference in SGN density among the groups (two-way ANOVA, p = 0.76), and the 2.5 J/cm2 group showed significantly lower survival rates of SGN compared to the control groups (two-way ANOVA, 2.5 J/cm2, p = 0.007). However, 2.0 and 2.25 J/cm2 groups showed comparable SGN survival compared to the controls. This result indicates that the severity of cochlear degeneration and hearing dysfunction depends on the LISW energy exposure, which is consistent with the ABR and HC survival results.

Stereociliary bundle
We observed a notable increase in the ABR threshold, approximately 30 dB, in both the 2.25 and 2.5 J/cm2 groups at frequencies above 20 kHz, which persisted up to 1 month following LISW exposure (as shown in Figure 2A). However, the 30-dB threshold shift we observed cannot be solely attributed to the loss of OHCs, degeneration of cochlear synapses, or a reduced number of SGCs (Figure 3). A previous study indicated that the ABR threshold shifts were minimal when the number of synaptic ribbons decreased by 50%19. Therefore, we performed SEM to investigate the cause of ABR threshold elevation. Following LISW exposure at an intensity of 2.5 J/cm2, some stereociliary bundles of OHCs appeared to be disrupted, particularly in high-frequency regions (Figure 4A), which may be one of the causes of enhanced ABR threshold following LISW exposure. Quantitative assessment of stereociliary disruption revealed that the disruption ratio tended to be higher in the higher-frequency region in an energy-dependent manner (Figure 4B).

Figure 1
Figure 1: Experimental settings and pressure profile of LISW. (A) Experimental setup for generating LISW in animals. (B) Characteristics of the LISW pressure waveforms set at 2.0 J/cm2. (C) Representative images of the tympanic membrane. TMPs were not observed in any of the LISW-exposed ears. As a reference, representative blast-induced TMP (yellow arrowheads) is shown using a blast tube. Abbreviations: LISW = laser-induced shock wave; PET = polyethylene terephthalate; TMP = tympanic membrane perforation; YAG = yttrium aluminum garnet; SHG = second harmonic generation. Please click here to view a larger version of this figure.

Figure 2
Figure 2: ABR results after exposure to LISW. (A) Significant ABR threshold shifts were observed in all groups 1 day after exposure to LISW. The ABR threshold shifts in the 2.25 and 2.5 J/cm2 groups remained significantly elevated for up to 1 month after exposure to LISW. (B) The ABR P1 amplitude 1 day and 1 month after exposure to LISW significantly decreased in all the groups. Asterisks indicate significant differences among groups compared to the preexposure values (**p < 0.001, ****p < 0.0001). Error bars indicate the standard error of the mean. Abbreviations: ABR = auditory brainstem response; LISW = laser-induced shock wave; P1 = peak 1; SPL = sound pressure level. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Cochlear pathology after exposure to LISW. (A) Confocal fluorescence images of the organ of Corti in the 20 kHz region stained with Myo7A (blue), CtBP2 (red), and NF (green) following exposure to LISW. (B) The average percentages of surviving HCs are shown in the cytocochleograms. Quantitative assessment revealed a significant loss of OHCs at 2.5 J/cm2, although there was no significant difference in IHC survival between groups. (C) The survival rate of presynaptic ribbons compared to pre-exposure values was significantly decreased in the 2.25 and 2.5 J/cm2 groups. (D) Representative photomicrographs of SGNs in all groups 1 month after exposure to LISW. The SGN survival rate decreased significantly at 2.5 J/cm2. Asterisks indicate significant differences compared to pre-exposure values (**p < 0.001, ****p < 0.0001). Error bars indicate the standard error of the mean. Scale bars = 5 µm (A), 100 µm (D). Abbreviations: LISW = laser-induced shock wave; IHC = inner hair cell; NF = neurofilament; OHC = outer hair cell; SGN = spiral ganglion neuron. Please click here to view a larger version of this figure.

Figure 4
Figure 4: Surface structures of OHCs. (A) Representative scanning electron microscopy images of OHC stereocilia in the 16 kHz and 24 kHz regions of the organ of Corti one month after exposure to LISW. Stereociliary disruption is seen in enlarged images of the boxed area in the 2.5 J/cm2 (24 kHz area) group. Scale bar -= 2 µm. (B) The stereociliary disruption rate was higher with an increase in LISW overpressure. Abbreviations: LISW = laser-induced shock wave; OHC = outer hair cells. Please click here to view a larger version of this figure.

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Discussion

This study aimed to validate a mouse model of blast-induced cochlear damage using LISW. Our findings demonstrated that following LISW application through the temporal bone, the exposed mice ear exhibited a consistent pathological and physiological decline in the cochlea, which was accompanied by an increase in LISW overpressure. These results indicate that this mouse model is appropriate for replicating various cochlear pathologies by adjusting the LISW output. Specifically, this LISW-induced cochlear dysfunction mouse model could serve as a good cochlear injury model because of its controlled, reproducible, and quantifiable nature, as well as its ability to reproduce pathophysiological cochlear decline under controlled conditions.

Our previous study used a rat model and observed LISW-induced cochlear degeneration, including elevation of hearing thresholds, loss of synaptic ribbons, and stereociliary bundle disruption14. Another study investigated pathophysiological cochlear degeneration following blast injury in mice using two types of blasts with different characteristics: low-frequency dominant using a blast tube and high-frequency dominant using LISW15. They determined that the dominant frequency of the blast power spectrum was the principal factor in determining the region of cochlear damage, as previously reported15. To the best of our knowledge, this is the first study to demonstrate the detailed methodology of LISW cochlear exposure and the energy- and frequency-dependent LISW-induced cochlear degeneration.

We utilized LISW exposure to damage the cochlea through the postauricular temporal bone rather than through the external auditory canal to create a model that solely involved cochlear damage without any TMP or ossicular chain discontinuation. Our findings imply that the hearing impairment demonstrated in this study was due to the deterioration of the sensorineural components in the auditory pathway. Recent studies have indicated that the TMP can serve as a buffer against damage to the cochlea by absorbing SW energy2,20,21. This LISW model was unable to induce TMP, even with high-intensity LISW, because the SW was directly irradiated into the inner ear and not through the tympanic membrane. Therefore, to analyze mixed hearing loss with TMP and SNHL, a high-intensity blast generated using a real explosion or shock tube is ideal. The choice of the blast type depends on the specific use or aim of the study. Therefore, this LISW-based animal injury model is useful for elucidating pure blast-induced cochlear pathophysiology without TMP, resulting in conductive hearing loss. From another perspective, LISW irradiation required 1 h/animal, including setting up the equipment and checking the tympanic membrane after irradiation. Therefore, if several animals were exposed to LISW in a row within 1 day, it is difficult to measure LISW irradiation and ABR on the same day with a single anesthetic dose. Because of the risk of animal death when increasing the anesthetic dose, in this study, we decided to perform ABR measurements the following day, not immediately after irradiation on the same day.

In the blast injury, the primary phase is caused by the physical forces of the explosion and rapid SW transmission with significant changes in tissue density, such as tissue-air junctions22. Therefore, most blast-induced cochlear injuries are considered to arise from the SW during the primary phase6, suggesting that studies on SW-exposed cochlear injuries are crucial for understanding the mechanisms of blast-induced cochlear dysfunction. The creation of an SW using a high-energy laser pulse on a solid material is known as LISW. Previous studies have used LISW to develop animal models of blast-induced traumatic brain and pulmonary injuries16,17. The benefits of using LISW for blast-related studies include its laser intensity-dependent repeatable damage model and specific targeting of the injured organ because LISW does not impact areas outside the targeted area.

In this study, we discovered that LISW elicits pathological changes in cochlear HCs, SGNs, their synapses, and the stereociliary bundle, similar to the damage caused by real blast injury12. The damage inflicted by various forms of cochlear insults, such as noise-induced hearing loss, can be attributed to two fundamental factors: direct mechanical stress and secondary metabolic disruption. We propose that disruption of the stereociliary bundle is the primary pathology resulting from direct mechanical stress of the LISW. Stereociliary disturbances are common pathologies associated with age-related and noise-induced hearing dysfunction23,24. The exact mechanism underlying this stereociliary disruption has not yet been elucidated. A previous study revealed that stereociliary disruption was observed 1 week after blast exposure12. A possible reason for this unique morphological change may be the disconnection of tip links and side links between the disturbed outermost row stereocilia and the middle row stereocilia14. Furthermore, rootlets of the outermost row of stereocilia, which consist of actin and bundling proteins, such as TRIOBP, are also mechanically damaged15.

Cochlear insults usually lead to further disruption of metabolic processes that can persist for days or even months19. In particular, the synapses in the cochlea, which are responsible for auditory sound processing, are highly vulnerable to blast exposure25.Our animal models showed that the degeneration of ANs function, as demonstrated by the decline in ABR P1 amplitudes, was caused by LISW-induced cochlear damage. One possible mechanism of LISW-induced cochlear synaptopathy is excessive glutamate release by the IHCs, such as glutamate ototoxicity26. LISW exposure causes the basilar membrane to vibrate violently, causing excessive release of glutamate from the IHC, which results in AN degeneration.LISW can replicate the type of glutamate toxicity that affects the cochlea, leading to cochlear synaptopathy and a decline in the number of synapses without damaging HCs. Another possible mechanism is that LISW exposure may damage cochlear supporting cells, which contributes to the survival of ANFs depending on the release of neurotrophins27. In addition, LISW may be transmitted directly to ANFs and cause neural damage. Consequently, our LISW-induced cochlear damage models could be valuable for both blast research and the examination of diverse forms of cochlear degeneration that involve cochlear synaptopathy.

There is an urgent need for therapeutic interventions to address blast-induced hearing loss, highlighting the significance of treatment strategies focusing on cochlear synaptopathy or stereociliary bundle disruption in OHC. These approaches can also be applied to other types of hearing disorders with similar pathological mechanisms. Cochlear synaptopathy was observed in our blast-induced cochlear dysfunction model, suggesting that it may be a promising therapeutic target. LISW can be used to create mouse models that accurately replicate the cochlear pathophysiology caused by blasts, and these models can be used to study various types of cochlear dysfunctions.

Our study has several limitations. First, we measured the ABR thresholds at 12-24 kHz. According to a previous study, LISW-induced cochlear damage results in high-frequency hearing loss in animals because of the characteristics of SW and the vulnerability of the cochlear base. Further ABR studies are necessary in wider frequency regions (>24 kHz). Second, in this study, we only conducted a histological evaluation of the cochlea and did not evaluate the central auditory pathway. Hearing impairment in blast injury is not only limited to the cochlea but is a complicated impairment of the brainstem and central auditory system. In the future, it would be desirable to evaluate the auditory center in LISW-exposed animal models.

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Disclosures

The authors declare that they have no conflicts of interest.

Acknowledgments

This work was supported by two grants from JSPS KAKENHI (Grant Numbers 21K09573 (K.M.) and 23K15901 (T.K.)).

Materials

Name Company Catalog Number Comments
532 nm Q-switched Nd:YAG laser  Quantel Brilliant b
ABR peak analysis software Mass Eye and Ear N/A EPL Cochlear Function Test Suite
Acrylic resin welding adhesive  Acrysunday Co., Ltd N/A
confocal fluorescence microscopy Leica TCS SP8
cryosectioning compound Sakura Tissue-Tek O.C.T
CtBP2 antibody BD Transduction #612044
Dielectric multilayer mirrors SIGMAKOKI CO.,LTD TFMHP-50C08-532 M1-M3
Digital oscilloscope Tektronix DPO4104B
Earphone CUI CDMG15008-03A
Hydrophone RP acoustics e.K. FOPH2000
Image J software plug-in NIH measurement line https://myfiles.meei.harvard.edu/xythoswfs/webui/_xy-e693768_1-t_wC4oKeBD
Light microscope Keyence Corporation BZ-X700
Myosin 7A antibody Proteus Biosciences #25–6790 
Neurofilament antibody Sigma #AB5539
Plano-convex lens SIGMAKOKI CO.,LTD SLSQ-30-200PM
Prism software GraphPad N/A ver.8.2.1
Scanning electron microscope JEOL Ltd JSM-6340F
Small digital endoscope AVS Co. Ltd AE-C1
Ultrasonic jelly Hitachi Aloka Medical N/A
Variable attenuator Showa Optronics Co. N/A Currenly avaiable successor: KYOCERA SOC Corporation, RWH-532HP II
Water-soluble encapsulant  Dako #S1964

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Kurioka, T., Mizutari, K., Niwa, K., More

Kurioka, T., Mizutari, K., Niwa, K., Kimura, E., Kawauchi, S., Kobayashi, Y., Sato, S. Research Application of Laser-Induced Shock Wave for Studying Blast-Induced Cochlear Injury. J. Vis. Exp. (205), e66396, doi:10.3791/66396 (2024).

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